Disclosed is a rack, or carrier, mountable to a vehicle and components for a rack. The rack in a preferred embodiment of the invention is a bike rack. In other preferred embodiments, the rack may be a utility rack for carrying other items, tools, or equipment. The rack includes a carrier portion on which one or more items can be loaded, a vehicle-coupling portion pivotably coupled to the carrier portion, the vehicle-coupling portion being couplable to a vehicle, and a linkage for connecting the carrier portion to the vehicle-coupling portion. The linkage is configured to bias the carrier portion to a substantially upright position relative to the vehicle-coupling portion when the vehicle-coupling portion is coupled to the vehicle, and to support the carrier portion relative to the vehicle-coupling portion when the carrier portion is in a lowered position and loaded with one or more items.

The present disclosure discloses a two-suction-cup vehicle-mounted support fixing device, including a mounting seat and a suction cup main body; a cylinder channel is formed in the mounting seat; a pressure valve switch is arranged in the cylinder channel; one end of the suction cup main body is embedded to a bottom of the mounting seat, and the other end of the suction cup main body extends into the cylinder channel and is hinged with the pressure valve switch; the suction cup main body includes an outer suction cup and at least one inner suction cup located on an inner side of the outer suction cup; a pull handle is also arranged on one side of the suction cup main body; and a support connector is arranged at one end of the mounting seat.

An adapter device for a vehicle includes a rail unit installed in the vehicle and defining a moving path, and an adapter unit mounted on the rail unit to move along the moving path, with a connector for mounting various convenience equipment being interchangeably coupled to the adapter unit.

A vehicular driver monitoring system includes an interior rearview mirror assembly having a mirror head accommodating a mirror reflective element and adjustable about a mounting structure. The mirror head is adjustable relative to the mounting structure to adjust a rearward view provided by the mirror reflective element. A driver monitoring camera is accommodated by the mirror head behind the mirror reflective element. With the mirror head adjusted to provide the rearward view, a normal vector extending perpendicular to the mirror reflective element is directed toward a driver side of the cabin of the vehicle and, responsive to determination that a passenger is present at a passenger side of the cabin of the vehicle, a principal viewing axis of the driver monitoring camera is angled more toward a centerline axis of the vehicle than the normal vector of the mirror reflective element.

A vehicle may receive one or more images of an environment of the vehicle. The vehicle may also receive a map of the environment. The vehicle may also match at least one feature in the one or more images with corresponding one or more features in the map. The vehicle may also identify a given area in the one or more images that corresponds to a a portion of the map that is within a threshold distance to the one or more features. The vehicle may also compress the one or more images to include a lower amount of details in areas of the one or more images other than the given area. The vehicle may also provide the compressed images to a remote system, and responsively receive operation instructions from the remote system.

A robotic vehicle for traversing surfaces comprises a chassis having a plurality of wheels mounted thereto. Two magnetic drive wheels are spaced apart in a lateral direction and rotate about a rotational axis while a stabilizing wheel is provided in front of or behind the two drive wheels. The drive wheels are configured to be driven independently, thereby driving and steering the vehicle along the surface. The vehicle also includes a sensor probe assembly that is supported by the chassis and configured to take measurements of the surface being traversed. In accordance with a salient aspect, the vehicle includes a probe normalization mechanism that is configured to determine the surface curvature and adjust the orientation of the probe transducer as a function of the curvature of the surface, thereby maintaining the probe at the preferred inspection angle irrespective of changes in the surface curvature with vehicle movement.

An inflatable system includes a first bladder configured to contain gas and a second bladder configured to contain gas. The first bladder includes a top wall, a bottom wall opposite of the top wall, a sidewall extending between and connected to perimeter edges of the top and bottom walls, and a plurality of tethers extending between and connected to interior surfaces of the top and bottom walls. The second bladder includes a top wall, a bottom wall opposite of its top wall, a sidewall extending between and connected to perimeter edges of its top and bottom walls, and a plurality of tethers extending between and connected to interior surfaces of its top and bottom walls. The bottom wall of the first bladder is secured to the top wall of the second bladder.

An unmanned aerial vehicle (UAV) includes a body constructed to enable the UAV to fly and three or more legs connected to the body and configured to land and perch the UAV on a curved ferromagnetic surface. Each leg includes a first portion connected to the body, a second portion including a magnet and configured to magnetically attach and maintain the magnetic attachment of the leg to the ferromagnetic surface during the landing and perching, and a passive articulation joint connecting the first and second portions and configured to passively articulate the second portion with respect to the first portion in response to the second portion approaching the ferromagnetic surface. The UAV further includes a releasable crawler including magnetic wheels which detach the crawler from the body during the perching and maneuver the crawler on the ferromagnetic surface while magnetically attaching the crawler to the ferromagnetic surface after detachment.

A vehicle may receive one or more images of an environment of the vehicle. The vehicle may also receive a map of the environment. The vehicle may also match at least one feature in the one or more images with corresponding one or more features in the map. The vehicle may also identify a given area in the one or more images that corresponds to a portion of the map that is within a threshold distance to the one or more features. The vehicle may also compress the one or more images to include a lower amount of details in areas of the one or more images other than the given area. The vehicle may also provide the compressed images to a remote system, and responsively receive operation instructions from the remote system.

An accessory adapter comprising a vehicle side, attachable to one or more hinges of a vehicle, and an accessory side, wherein the accessory side is configured to accept an accessory. Including a method of attaching the accessory adapter to a vehicle.